WO2021130857A1 - Method for manufacture of shoe and shoe - Google Patents

Abstract

Provided are a method for manufacture of shoe and shoe which can be manufactured by said method for manufacture, said method comprising: a sheet preparation step of preparing a bonding sheet comprising at least a first thermoplastic resin and an energy absorbent material having a higher dielectric loss rate than the first thermoplastic resin, wherein the first thermoplastic resin is exposed on at least a first surface of the bonding sheet from among the first surface of the bonding sheet and a second surface of the bonding sheet on the reverse side from the first surface; a contact step of bringing a first adherend surface formed on a first shoe member in contact with the first surface and bringing a second adherend surface formed on a second shoe member in contact with the second surface; and a bonding step of, after the contact step, causing the bonding sheet to heat fuse by irradiating the bonding sheet with microwaves, and bonding the first shoe member to the second shoe member via the bonding sheet.

Description

How to make shoes and shoes

The present invention relates to a method for manufacturing shoes using microwave irradiation, and shoes that can be manufactured by the manufacturing method.

In the shoe manufacturing process, when adhering a plurality of shoe members to each other, the hot melt adhesive used for adhering the shoe members is irradiated with a microwave, thereby applying the hot melt adhesive. A method of heating and melting may be used.

Such a microwave heating method has an advantage that only the hot melt adhesive, which is an adhesive element, can be selectively heated while suppressing the heating of the shoe member to be bonded at the time of bonding the shoe member. Have.
For example, in Patent Document 1, a hot melt adhesive layer is provided between a plurality of foamed thermoplastic polyurethane particles and a surface of rubber or the like, and then the hot melt adhesive is microwave-heated by irradiating with microwaves. It discloses a method of manufacturing a shoe member by adhering the polyurethane particles and the surface thereof.

However, in the conventional method, the hot melt adhesives that can be selected are limited to those composed of a thermoplastic resin that can absorb the irradiated microwaves and be heated and melted. Therefore, there is a problem that the shoe member that can be adhered by this method is limited to the one having a surface to be adhered that can be adhered well to such a thermoplastic resin.

Therefore, there is a need for a method of expanding the adhesive elements that can be used in the shoe manufacturing process using the microwave heating method.

JP-A-2017-061143

The present invention provides a method capable of easily adhering a shoe member by microwave heating while using a thermoplastic resin which is normally difficult to heat by microwave as an adhesive element of the shoe member. The purpose.
It is also an object of the present invention to provide shoes that can be easily manufactured by the above method.

The present invention
An adhesive sheet containing at least a first thermoplastic resin and an energy absorbing material having a higher dielectric loss rate than the first thermoplastic resin, the first surface of the adhesive sheet and the first surface of the adhesive sheet. A sheet preparation step of preparing an adhesive sheet, wherein the first thermoplastic resin is exposed on at least the first surface of the second surface opposite to the surface of the above.
The first adhered surface formed on the first shoe member is brought into contact with the first surface, and the second adhered surface formed on the second shoe member is brought into contact with the second surface. With the contact step to bring it into contact with
After the contact step, the adhesive sheet is heated and melted by irradiating the adhesive sheet with microwaves, and the first shoe member and the second shoe member are used for adhesion. Provided is a method of manufacturing a shoe, which comprises an gluing step of gluing through a sheet.

In addition, the shoes according to the present invention
An adhesive sheet containing a first thermoplastic resin and an energy absorbing material having a higher dielectric loss with respect to microwave waves than the first thermoplastic resin, and the first surface of the adhesive sheet. An adhesive sheet having the first thermoplastic resin exposed on at least the first surface of the second surface opposite to the first surface.
The first shoe member adhered to the first surface and
It includes a second shoe member adhered to the second surface.

The side view which showed the manufacturing method of the shoe of one embodiment, and an example of the adhesive sheet which can be used for a shoe. The side view which showed the manufacturing method of the shoe of this disclosure and another example of the adhesive sheet which can be used for a shoe. The side view which showed the manufacturing method of the shoe of one embodiment and still another example of the adhesive sheet which can be used for a shoe. The side view which showed the manufacturing method of the shoe of one embodiment and still another example of the adhesive sheet which can be used for a shoe. The schematic which showed the contact step in one Embodiment of the shoe manufacturing method. The schematic which showed the bonding step in one Embodiment of the shoe manufacturing method. A side view showing a shoe according to a method of manufacturing a shoe and an embodiment of the shoe.

(Shoe manufacturing method)
An embodiment of the present invention will be described below.
In the method for manufacturing shoes of the present embodiment, an adhesive sheet is used.
In the shoe manufacturing method of the present embodiment, the first shoe member and the second shoe member are bonded by the adhesive sheet.
The adhesive sheet contains at least a first thermoplastic resin and an energy absorbing material having a higher dielectric loss rate than the first thermoplastic resin.
The adhesive sheet has the first thermoplastic resin exposed on at least the first surface of the first surface and the second surface opposite to the first surface.
In the shoe manufacturing method of the present embodiment, a sheet preparation step for preparing such an adhesive sheet is carried out.

In the method for manufacturing a shoe of the present embodiment, the first surface to be adhered to the first shoe member is brought into contact with the first surface of the adhesive sheet, and the first surface of the adhesive sheet is brought into contact with the first surface to be adhered. A contact step is further carried out in which the second surface to be adhered formed on the second shoe member is brought into contact with the surface of 2.

In the method for manufacturing shoes of the present embodiment, after the contact step, the adhesive sheet is heated and melted by irradiating the adhesive sheet with microwaves to heat and melt the adhesive sheet, and the first shoe member and the first shoe member. An adhesive step of adhering the shoe member of 2 to the adhesive sheet via the adhesive sheet is further carried out.

In the description of the shoe manufacturing method of the present specification, when the term "microwave" is simply used, it means the microwave irradiated in the bonding step of irradiating the microwave, unless otherwise specified. Say.
Similarly, when the term "dielectric loss rate" is used in the description of each of the embodiments, it means the dielectric loss rate with respect to the frequency of the microwave. This dielectric loss rate can be obtained by measurement with an LCR meter or measurement with a cavity resonator perturbation method, although it depends on the frequency of the microwave.

According to this method, the thermoplastic resin contained in the adhesive sheet can be heated and melted by the heat of the energy absorbing material heated by the microwave. Therefore, it is possible to easily bond the shoe member by microwave heating while using a thermoplastic resin which is normally difficult to heat by microwave as an adhesive element of the shoe member.

(Adhesive sheet)
First, the adhesive sheet used in the method for manufacturing shoes of the present embodiment will be described with reference to the examples of FIGS. 1 to 4.

The adhesive sheet contains at least a first thermoplastic resin and an energy absorbing material having a higher dielectric loss rate than the first thermoplastic resin, and the first thermoplastic resin is the first thermoplastic resin of the adhesive sheet. The first thermoplastic resin is exposed on at least the first surface of the surface of 1 and the second surface opposite to the first surface.

The first thermoplastic resin is a resin that is at least adhered to the adhered surface (hereinafter, also referred to as the first adhered surface) of the first shoe member on the first surface of the adhesive sheet.
The first thermoplastic resin is, for example, a polyolefin resin such as a polyethylene (PE) resin or a polypropylene (PP) resin, a thermoplastic polyurethane (TPU) resin, a polystyrene (PS) resin, an ethylene-propylene rubber (EPDM), or a polyether. It can be a resin that can be bonded to the first surface to be bonded from any thermoplastic resin including blockamide (PEBA) resin, polyester (PEs) resin, ethylene vinyl acetate (EVA) resin, polyamide (PA) resin, and the like. ..
Preferably, as the first thermoplastic resin, a resin having a melting point or a softening point in the range of 70 ° C. to 140 ° C. and functioning as a hot melt adhesive is selected. By using such a resin, it becomes possible to easily and efficiently heat and melt the first thermoplastic resin in a later bonding step.
Further, the first thermoplastic resin is preferably a resin of the same type as the resin exposed on the first surface to be adhered, from the viewpoint of adhesiveness to the first shoe member. For example, when the EVA resin is exposed on the first surface to be adhered, the first thermoplastic resin may also be an EVA resin.

The energy absorbing material can be any material that has a higher dielectric loss rate than the first thermoplastic resin and can absorb microwaves to generate heat. The energy absorber is appropriately selected according to the frequency of the irradiated microwave, and may be a thermoplastic resin such as a thermoplastic polyurethane (TPU) resin or a polyamide (PA) resin, and may be a thermosetting polyurethane. It may be a thermosetting resin such as a thermoplastic elastomer, an acrylic elastomer, a crosslinked rubber, a silicone elastomer or a fluorine elastomer, or may be a material other than a resin such as water, magnesium oxide or titanium oxide.
Preferably, the energy absorber can be a different type of thermoplastic resin than the first thermoplastic. For example, when the first thermoplastic resin is an EVA resin, the energy absorbing material may be a TPU resin.
When the energy absorbing material is a thermoplastic resin, a resin having a melting point or a softening point in the range of 70 ° C. to 140 ° C. and functioning as a hot melt adhesive is more preferably selected. By using such a resin, it becomes possible to easily and efficiently heat and melt the energy absorbing material in the subsequent bonding step.

The dielectric loss rate of the energy absorbing material is preferably 0.01 (εr · tan δ) or more. In that case, the energy absorbing material can be efficiently heated by irradiation with microwaves. More preferably, the dielectric loss rate of the energy absorbing material is 0.1 (εr · tan δ) or more. The dielectric loss rate of the first thermoplastic resin may be a value 0.01 or more lower than the dielectric loss rate between the first thermoplastic resin and the energy absorbing material, or may be 0.1 or more lower.

The adhesive sheet may contain any component other than the above-mentioned first thermoplastic resin and energy absorbing material. For example, the adhesive sheet may contain an additional thermoplastic resin different from the first thermoplastic resin and the energy absorbing material described above. In addition, the adhesive sheet may further contain chemicals such as a dye, an antioxidant, and an ultraviolet absorber.

As described above, the first surface of the adhesive sheet is the surface to be adhered to the surface to be adhered to the first shoe member, and is the surface on which the first thermoplastic resin is exposed.
On the other hand, the first thermoplastic resin is exposed on the second surface of the adhesive sheet, which is the surface to be adhered to the adhered surface of the second shoe member (hereinafter, also referred to as the second adhered surface). In addition or instead, a second resin different from the first thermoplastic resin, preferably a second thermoplastic resin, may be exposed.

When a second resin different from the first thermoplastic resin is exposed on the second surface of the adhesive sheet, the first surface of the adhesive sheet can be adhered to the first thermoplastic resin. It is possible to bond the first shoe member having the first surface to be adhered to the second surface, which may not be able to adhere to the first thermoplastic resin. A second shoe member having a second surface to be adhered can be adhered. That is, by using such an adhesive sheet, it becomes possible to bond two shoe members having different adhesiveness to the resin via the adhesive sheet.

Preferably, on the first surface of the adhesive sheet, the abundance ratio of the first thermoplastic resin is larger than the abundance ratio of the second resin different from the first resin, and on the second surface, the said The abundance ratio of the second resin is larger than the abundance ratio of the first thermoplastic resin. In such a case, the adhesiveness of the first thermoplastic resin on the first surface and the adhesiveness of the second resin on the second surface can be more effectively exhibited.
The abundance ratio of each resin on the first and second surfaces can be measured by, for example, Fourier transform infrared spectroscopy (FT-IR) by the diamond ATR method.

The second resin exposed on the second surface may be the above-mentioned energy absorbing material. That is, the adhesive sheet contains a first thermoplastic resin and a second resin having a higher dielectric loss rate than the first thermoplastic resin, and a first surface of the adhesive sheet has a first surface. The adhesive sheet may be an adhesive sheet in which the thermoplastic resin is exposed and the second thermoplastic resin is exposed on the second surface of the adhesive sheet. In such a case, since the second resin that controls the adhesiveness of the second adhesive surface also serves as an energy absorber, it can be easily heated by microwaves while reducing the use of materials that do not contribute to the adhesive function. An adhesive sheet can be prepared.

However, the second resin may be another material different from the first thermoplastic resin and the above-mentioned energy absorbing material. That is, even if the adhesive sheet separately contains the first thermoplastic resin exposed on the first surface, the second resin exposed on the second surface, and the energy absorber. Good.

The thickness of the adhesive sheet is not particularly limited, but is preferably 100 μm or more in order to secure the amount of the thermoplastic resin contained in the adhesive sheet. Further, it is preferably 1,500 μm or less in consideration of the influence on the flexibility of the shoe.
Further, in order to facilitate the transfer of the heat of the energy absorbing material to the first thermoplastic resin when the energy absorbing material is microwave-heated, the distance between the first thermoplastic resin and the energy absorbing material in the adhesive sheet. Is preferably within 50 μm. When the adhesive sheet contains a material heated by an energy absorbing material (for example, a second thermoplastic resin) in addition to the first thermoplastic resin, such a material and the energy absorbing material Similarly, the distance from and is preferably within 50 μm.

The thickness of the adhesive sheet may be changed according to the part in consideration of the flexibility required for the adhesive sheet and the like. For example, the thickness of the adhesive sheet can be reduced in a portion of the sole member corresponding to a portion (flexibility imparting portion) that supports the MP joint of a standard human foot and its vicinity.

FIG. 1 shows an example of an adhesive sheet. The adhesive sheet 10 contains a first spare sheet 11 containing the first thermoplastic resin 111 as a main component and a second thermoplastic resin 121 of a type different from that of the first thermoplastic resin 111 as a main component. A second spare sheet 12 is provided, and the first spare sheet 11 and the second spare sheet 12 are laminated. That is, in this example, the first thermoplastic resin 111 is exposed on one surface (first surface 10A) of the adhesive sheet, and the second surface (second surface 10B) is exposed. The thermoplastic resin 121 is exposed. In this example, the second thermoplastic resin 121 functions as an energy absorber.

It is preferable that the first spare sheet 11 and the second spare sheet 12 are adhered by an arbitrary method. In this case, the adhesive sheet 10 can be easily handled. For example, the first spare sheet 11 and the second spare sheet 12 may be adhered to each other via a primer. Examples of the primer used for adhering the spare sheets 11 and 12 to each other include an EVA-based primer containing EVA. Primers include water-based primes such as polyolefin-based emulsions, EVA-based emulsions, acrylic-based emulsions, and urethane-based emulsions, acrylic resin-based primes, polyamide-based primes, olefin-based primes, phenol-resin-based primes, polyester-based primers, and polyurethane-based primers. It may be a chloroprene rubber-based primer or the like. Alternatively, the first spare sheet 11 and the second spare sheet 12 may be adhered only by the adhesive force of the resins 111 and 121 exposed on the surfaces where the spare sheets 11 and 12 are in contact with each other. The resins 111 and 121 may be adhered by being heated and melted.

However, the first spare sheet 11 and the second spare sheet 12 may be integrated by any method other than adhesion. Further, the first spare sheet 11 and the second spare sheet 12 do not necessarily have to be integrated, and an aggregate in which the two separated spare sheets 11 and 12 are laminated is used as the adhesive sheet 10. It may be defined. In this case, the two spare sheets 11 and 12 are integrated at the time of microwave irradiation.

The thicknesses of the first and second spare sheets 11 and 12 are appropriately selected according to the thickness of the adhesive sheet 10, and may be in the range of, for example, 150 μm to 1,000 μm. The thickness of the first spare sheet 11 and the thickness of the second spare sheet 12 may be the same or different.
These thicknesses may be changed depending on the site in consideration of the flexibility required for the adhesive sheet 10 and the like. For example, the thickness of the first and second spare sheets 11 and 12 can be reduced in the portion of the sole member corresponding to the flexibility-imparting portion.

FIG. 2 shows another example of the adhesive sheet. The adhesive sheet 20 is different from the first thermoplastic resin 211 between the first and second spare sheets 21 and 22 containing the first and second thermoplastic resins 211 and 221 as main components, respectively. A third spare sheet 23 containing a third type of thermoplastic resin 231 as a main component is provided, and these three spare sheets are the first spare sheet 21, the third spare sheet 23, and the third from the bottom. The spare sheets 22 of 2 are laminated in this order. In this example, the third thermoplastic resin 231 functions as an energy absorber.
In this example, the second thermoplastic resin 221 is made of a different kind of resin from the first thermoplastic resin 211, but may be made of the same kind of resin instead. That is, the types of the resins 211 and 221 exposed on the first and second surfaces 20A and 20B of the adhesive sheet 20 are different types, but they may be the same type.

These spare sheets 21 to 23 are also preferably bonded by any method as in the example of the bonding sheet 10 shown in FIG. 1, but may be integrated by a method other than bonding. , It does not have to be integrated. When the spare sheets 21 to 23 are integrated, the adhesive sheet 10 can be easily handled. On the other hand, when the spare sheets 21 to 23 are not integrated, the adhesive sheet 10 is integrated by microwave irradiation in the bonding step.

Similarly, the thicknesses of these spare sheets 21 to 23 are appropriately selected according to the thickness of the adhesive sheet 20, and may be in the range of, for example, 150 μm to 1,000 μm. The thicknesses of the first, second and third spare sheets 21 to 23 may be the same or different from each other. These thicknesses may be changed depending on the site in consideration of the flexibility required for the adhesive sheet 10 and the like. For example, the thickness of the spare sheets 21 to 23 can be reduced in the portion of the sole member corresponding to the flexibility-imparting portion.

FIG. 3 shows yet another example of the adhesive sheet. The adhesive sheet 30 is a single polymer blend made of a first thermoplastic resin 311 and a second thermoplastic resin 321 of a type different from the first thermoplastic resin 311. It is composed of sheets. In this example, the second thermoplastic resin 321 functions as an energy absorber.
In this example, the polymer blend in the single sheet has a structure in which the first thermoplastic resin 311 and the second thermoplastic resin 321 are phase-separated, and is the first surface of the adhesive sheet. At 30A, the abundance ratio of the first thermoplastic resin 311 is larger than the abundance ratio of the second thermoplastic resin 321. On the second surface 30B, the abundance ratio of the second thermoplastic resin 321 is the above. It is larger than the abundance ratio of the first thermoplastic resin 311.

FIG. 4 shows yet another example of the adhesive sheet. The adhesive sheet 40 contains a first resin fiber 41 containing the first thermoplastic resin 411 as a main component and a second thermoplastic resin 421 of a type different from the first thermoplastic resin 411 as a main component. It has a structure in which the second resin fiber 42 is woven. In this example, the second thermoplastic resin 421 functions as an energy absorber.
In this example, the first and second resin fibers 41 and 42 are exposed on both the first and second surfaces 40A and 40B of the adhesive sheet 40, but on the first surface 40A, the first The abundance ratio of the resin fiber 41 is larger than the abundance ratio of the second resin fiber 42, and on the second surface 40B, the abundance ratio of the second resin fiber 42 is the abundance ratio of the first resin fiber 41. Is bigger than.

In addition to the configurations shown in FIGS. 1 to 4, the adhesive sheet of the present embodiment has a first thermoplastic resin different from the energy absorbing material as long as it is exposed on at least one surface. The thermoplastic resin and the energy absorbing material of 1 may have a configuration in which they are present in the adhesive sheet in any manner. For example, in the adhesive sheet, an energy absorbing material in an arbitrary form, for example, a powdery form, a fibrous form, a flaky form, or the like, is dispersed inside a single sheet containing a first thermoplastic resin as a main component. It may have a configuration.

Further, in the adhesive sheets shown in FIGS. 1 to 4, the energy absorbing material is a thermoplastic resin, but the energy absorbing material may be a thermosetting resin or an inorganic material. For example, an energy absorbing material made of a thermosetting resin or an inorganic material may be sandwiched between the first and second spare sheets containing the first and second thermoplastic resins as main components, respectively, and is inorganic. The energy absorbing material made of fibers may be woven with the resin fibers containing the first thermoplastic resin as a main component.

(Shoe parts)
As the first and second shoe members to be adhered in the method for manufacturing shoes of the present embodiment, any shoe member used for shoes is selected. As such a shoe member, for example, as the first and second shoe members, other sole members such as a midsole, an outsole, and a sockliner, and a shoe reinforcement member such as a heel counter and a shank. , Upper material, decorative material, etc.

The combination of the first shoe member and the second shoe member is not particularly limited, and any combination of the shoe members to be adhered in the manufacture of shoes is selected. For example, the combination of the first shoe member and the second shoe member includes a combination of a midsole and an upper material, a combination of a midsole and an outsole, a combination of a midsole and a shank, and an upper. And a combination with a heel counter. Preferably, the combination of the midsole and the upper material is selected as the combination of the first shoe member and the second shoe member.
Further, the first shoe member and the second shoe member may each be a part of a specific member that can be generally recognized as one shoe member. For example, the first shoe member and the second shoe member may be the first component and the second component of the midsole that are adhered to form one midsole.

The first and second shoe members are formed with first and second surfaces to be adhered to the first and second surfaces of the adhesive sheet, respectively.
As described above, the first surface to be adhered to the first shoe member is made capable of adhering to the first thermoplastic resin exposed on the first surface of the adhesive sheet. From the viewpoint of adhesiveness to the first surface, it is preferable that a resin of the same type as the first thermoplastic resin is exposed on the first surface to be adhered. For example, when the first thermoplastic resin is an EVA resin, the EVA resin may also be exposed on the first surface to be adhered.
The second surface to be adhered to the second shoe member is one of the resins exposed on the second surface of the adhesive sheet, preferably the abundance ratio on the second surface is compared with any other resin. It can be adhered to a large resin. For example, if the abundance ratio of the second thermoplastic resin on the second surface is larger than the abundance ratio of any other resin, the second surface to be adhered can be adhered to the second thermoplastic resin. It is said that. From the viewpoint of adhesiveness to the second surface, it is preferable that a resin of the same type as the resin exposed on the second surface is also exposed on the second surface to be adhered.

As long as the first and second bonded surfaces as described above are provided, the first and second shoe members are made of any material such as foam, rubber, cloth, metal, resin, and fiber. It may include one or more members. For example, the first or second shoe member may be a sole member made of foam.

(Embodiment of manufacturing method)
Next, the shoe according to the embodiment of the present invention uses the adhesive sheet 10 shown in FIG. 1 as the adhesive sheet, the first shoe member as the midsole 2, and the second shoe member as the upper material 3. The manufacturing method of No. 1 will be described. However, the following embodiments are merely examples. The present invention is not limited to the following embodiments.

First, a sheet preparation step for preparing the adhesive sheet 10 shown in FIG. 1 is performed.

The step may include making the adhesive sheet 10 from the spare members of the adhesive sheet 10 (in this embodiment, the first and second spare sheets 11, 12).
For example, in the step, after applying the above-mentioned primer for adhering them to at least one side of the first and second spare sheets 11 and 12, they are adhered through the surface to which the primer is applied. , The adhesive sheet 10 may be produced accordingly.

Next, as shown in FIG. 5, the first surface 10A of the adhesive sheet 10 is brought into contact with the first adhesive surface 2A of the midsole 2 which is the first shoe member, and for adhesion. A contact step is performed in which the second surface 10B of the sheet 10 is brought into contact with the second adhered surface 3B of the upper material 3 which is a second shoe member.
In the present embodiment, the adhered surface 2A of the midsole 2 and the adhered surface 3B of the upper material 3 are in close contact with the entire surfaces of the first and second surfaces 10A and 10B of the adhesive sheet 10, respectively. Be touched.

Optionally, the first surface 10A, the second surface 10B, before the first and second surfaces 10A, 10B and the first and second adherent surfaces 2A, 3B are brought into contact with each other in the step. A primer application step may be performed in which a primer is applied to at least one of the first surface to be adhered 2A and the second surface to be adhered 3B. In that case, it becomes possible to perform surface modification treatment of the first surface to be adhered 2A and the second surface to be adhered 3B. Further, by using an aqueous primer, the heating characteristics to the interface are improved due to the water contained inside. In order to exert the effect of improving the heating characteristics, it is preferable that after applying the aqueous primer, the process proceeds to the bonding step and microwave irradiation is performed before the water is completely lost by drying. Microwave irradiation is preferably carried out in a state where the coating film of the primer contains 0.1% or more of water. Similarly, when the adhesive sheet 10 is not integrated, the water-based primer may be applied to the first and second spare sheets 11 and 12 in the step.
Preferably, the primer applied in the primer application step is an aqueous primer. Examples of such an aqueous primer include polyolefin-based emulsions, EVA-based emulsions, acrylic-based emulsions, urethane-based emulsions, and the like.

In the contact step, the contact state of these surfaces may be preliminarily fixed by any method. For example, these surfaces may be preliminarily adhered to each other by the adhesive force of the resin itself exposed on the abutted surfaces, or by a double-sided tape, an adhesive tape, or the like.
In addition or instead of this, the contact surfaces between the first and second surfaces 10A and 10B are pressed by using a jig such as a clamp from the outside of the surfaces 2A and 3B to be adhered. By a method of holding the pinched state, a method of inserting a foot mold into the upper material 3, and a method of holding a state in which the contact surface is pressed toward the midsole 2 arranged below by the foot mold, etc. The contact surface may be physically fixed. A plurality of these fixing methods may be performed in combination.

After this contact step, as shown in FIG. 6, a bonding step is performed in which the bonding sheet 10 is heated and melted by irradiating the bonding sheet 10 with microwaves.
When the adhesive sheet 10 is irradiated with microwaves, the second thermoplastic resin 121, which is an energy absorbing material contained in the second spare sheet 12 forming a part of the adhesive sheet 10, emits the microwaves. It absorbs, which causes the second spare sheet 12 to generate heat. The heat of the second spare sheet 12 that has generated heat is transferred to the adjacent first spare sheet 11, and as a result, the heat is transferred to the entire adhesive sheet 10 and the entire adhesive sheet 10 is heated and melted. To.
In the adhesive sheet 10 heated and melted in this manner, the first thermoplastic resin 111 exposed on the first surface 10A is in contact with the first surface 10A, and the first cover of the midsole 2 is in contact with the first surface 10A. The second thermoplastic resin 121, which is adhered to the adhesive surface 2A and exposed on the second surface 10B, adheres to the second adhered surface 3B of the upper material 3 which is in contact with the second surface 10B. Will be done. As a result, the midsole 2 and the upper material 3 are adhered to each other via the adhesive sheet 10.

The frequency of the microwave irradiated in the step is a frequency at which the energy absorbing material contained in the adhesive sheet 10 can be heated. The frequency is determined according to the type of the energy absorbing material, and is, for example, in the range of 300 MHz to 300 GHz, preferably in the range of 600 MHz to 10 GHz, and more preferably in the range of 1,000 MHz to 3 GHz. Yes, for example, 2.4 GHz.
Further, the irradiation intensity and irradiation time of microwaves are not particularly limited, and the intensity and time can be set so that the energy absorbing material can be sufficiently heated to heat and melt the adhesive sheet 10.

In this step, as shown in FIG. 6, when the adhesive sheet 10 is irradiated with microwaves, even if the midsole 2 and the upper material 3 in contact with the adhesive sheet 10 are also irradiated with microwaves. Good. However, when the midsole 2 or the upper material 3 contains a portion that is not related to adhesion and can be heated by microwaves, as much as possible in order to avoid adverse effects due to heating of the portion. It is preferable to irradiate the microwave while avoiding the portion. Further, a shielding member may be used so that the portion is not irradiated with microwaves.

In this step, a method of using a clamp, a foot mold, or the like as described above while the adhesive sheet 10 is irradiated with microwaves or while the heated adhesive sheet 10 is in a molten state, or the like. The contact surfaces between the first and second surfaces 10A and 10B and the first and second bonded surfaces 2A and 3B may be pressed. By crimping the midsole 2 and the upper material 3 in this way, these can be more reliably bonded. A plurality of these crimping methods may be performed in combination.

The adhesion between the midsole 2 and the upper material 3 is usually performed by heating and melting the adhesive sheet 10 and then cooling the first and second thermoplastic resins 111 and 121 contained in the adhesive sheet 10. Is completed by solidifying. The method for cooling the heat-melted adhesive sheet 10 is not particularly limited, and for example, it is performed by simply leaving it in a room temperature environment.

By performing each of the above steps, the midsole 2 which is the first shoe member and the upper material 3 which is the second shoe member, as shown in FIG. 7, are connected to each other via the adhesive sheet 10. The bonded shoe 1 can be manufactured.
In this method, the second thermoplastic resin 121, which is an energy absorbing material contained in the adhesive sheet 10, is microwave-heated. Therefore, the heat generated heats the entire adhesive sheet 10 including the first thermoplastic resin 111. Can be melted. Therefore, even if the first thermoplastic resin 111 exposed on the first surface 10A of the adhesive sheet is a resin that is difficult to heat by microwaves, it is heated and melted by using microwaves to obtain the first and first and third thermoplastic resins. It can be used as an adhesive element for the second shoe members 2 and 3. Therefore, according to the manufacturing method of the shoe 1 of the present embodiment, it is possible to easily bond the shoe member by microwave heating while using a thermoplastic resin that is difficult to heat by microwave as an adhesive element of the shoe member.

Further, in the present embodiment, since the types of the first and second thermoplastic resins 111 and 121 exposed on the first and second surfaces 10A and 10B of the adhesive sheet 10 are different, the first and second surfaces are different. The adhesiveness of the surfaces 10A and 10B is different from each other. Therefore, the first and second shoe members 2 and 3 provided with the surfaces 2A and 3B to be adhered, which have different adhesiveness to the resin and are difficult to be directly adhered to each other, can be easily attached to each other via the adhesive sheet 10. It becomes possible to adhere to.

(shoes)
The shoe of the present embodiment is a shoe that can be manufactured by the above-mentioned shoe manufacturing method, for example, the shoe 1 shown in FIG.

The shoe of the present embodiment is an adhesive sheet containing a first thermoplastic resin and an energy absorbing material having a higher dielectric loss with respect to microwave waves than the first thermoplastic resin, and is used for the adhesion. An adhesive sheet and the first surface, wherein the first thermoplastic resin is exposed on at least the first surface of the first surface of the sheet and the second surface opposite to the first surface. It includes a first shoe member bonded to the surface of No. 1 and a second shoe member bonded to the second surface.

As the adhesive sheet, the first shoe member, and the second shoe member, those described with respect to the above-described shoe manufacturing method can be adopted.
In the description of shoes in the present specification, the “microwave” refers to an arbitrary electromagnetic wave having a frequency of 300 MHz to 300 GHz.

In the shoe of the present embodiment, the first shoe member and the second shoe member can be firmly adhered to each other via the adhesive sheet. Preferably, the adhesive strength between the first shoe member and the second shoe member is 6.25 kgf / 25 mm (180 degree peel strength in JIS K 6854) or more.

As described above, the method for manufacturing shoes according to the present embodiment is an adhesive sheet containing at least a first thermoplastic resin and an energy absorbing material having a higher dielectric loss rate than the first thermoplastic resin. Therefore, the first thermoplastic resin is exposed on at least the first surface of the first surface of the adhesive sheet and the second surface opposite to the first surface. A sheet preparation step for preparing a sheet for use and a second surface formed on the first shoe member to be adhered to the first surface and a second surface formed on the second shoe member are brought into contact with the first surface. After the contact step of bringing the surface to be adhered to the second surface and the contact step, the adhesive sheet is heated and melted by irradiating the adhesive sheet with microwaves to heat and melt the adhesive sheet. It is provided with an adhesive step for adhering the first shoe member and the second shoe member via the adhesive sheet.
According to the above invention, the shoe members can be easily bonded to each other by microwave heating while using the first thermoplastic resin, which is normally difficult to heat by microwaves, as an adhesive element of the shoe members. ..

In one aspect of the manufacturing method, the adhesive sheet contains a second thermoplastic resin of a type different from that of the first thermoplastic resin, and on the first surface, the first thermoplastic resin. The abundance ratio of the second thermoplastic resin is larger than the abundance ratio of the second thermoplastic resin, and the abundance ratio of the second thermoplastic resin is larger than the abundance ratio of the first thermoplastic resin on the second surface. In that case, the first and second shoe members having the first and second adhered surfaces, which have different adhesiveness to the resin and are difficult to be directly adhered to each other, are attached to each other. It becomes possible to easily bond the first and second thermoplastic resins through adhesive sheets having different abundance ratios on the surface of the first and second thermoplastic resins.

Preferably, the energy absorbing material is a thermoplastic resin, and may be the second thermoplastic resin. In that case, since the second thermoplastic resin that controls the adhesiveness of the second adhesive surface also serves as an energy absorber, it can be easily heated by microwaves while reducing the use of materials that do not contribute to the adhesive function. Adhesive sheets can be used. For example, the energy absorbing material may be a TPU resin.

The adhesive sheet may include two or more laminated spare sheets. In that case, the adhesive sheet can be easily produced by laminating a plurality of spare sheets containing different materials.

The first thermoplastic resin may be, for example, an EVA resin. The EVA resin is a resin that is relatively difficult to heat by microwaves, but according to the shoe manufacturing method of the present embodiment, even an adhesive sheet containing EVA resin is heated by microwaves. Therefore, EVA resin can be used as an adhesive element for shoe members. In this case, from the viewpoint of adhesiveness to the first shoe member, it is preferable that EVA resin or polyethylene resin is exposed on the first adhered surface of the first shoe member. ..

In the manufacturing method, at least one of the first surface, the second surface, the first bonded surface, and the second bonded surface is used before the contact step as described above. One surface may further be provided with a primer application step in which the aqueous primer is applied. The use of an aqueous primer is also advantageous in improving the working environment as compared with the case of using a primer in which an organic solvent is used as a solvent. This makes it easy to carry out the above manufacturing method even in a place other than a place such as a shoe manufacturing factory having an exhaust treatment facility.

Since the shoe manufacturing method of the present embodiment does not need to use a large-scale device, it can be easily carried out at a factory other than the shoe manufacturing factory. In particular, when a water-based primer is used, the adhesiveness between shoe members in the bonding step is improved, so that the equipment for irradiating microwaves can be miniaturized. Since this method can also reduce the environmental load, it can be carried out, for example, at a shoe store. Further, according to the shoe manufacturing method of the present embodiment, it is possible to manufacture shoes customized according to the user's preference by selecting a combination such as an upper and a midsole at a store. ..

Further, the shoe according to the present embodiment is an adhesive sheet containing a first thermoplastic resin and an energy absorbing material having a higher dielectric loss with respect to microwave waves than the first thermoplastic resin. An adhesive sheet having the first thermoplastic resin exposed on at least the first surface of the first surface of the adhesive sheet and the second surface opposite to the first surface. A first shoe member bonded to the first surface and a second shoe member bonded to the second surface.
According to the above invention, the present invention provides a shoe in which the shoe members are bonded to each other by microwave heating while using a first thermoplastic resin which is normally difficult to heat by microwaves as an adhesive element of the shoe members. be able to.

In one aspect of the shoe, the adhesive sheet contains a second thermoplastic resin of a different type than the first thermoplastic, and on the first surface, the first thermoplastic resin. The abundance ratio of the second thermoplastic resin is larger than the abundance ratio of the second thermoplastic resin, and the abundance ratio of the second thermoplastic resin is larger than the abundance ratio of the first thermoplastic resin on the second surface. In that case, the first and second shoe members having the first and second surfaces to be adhered, which have different adhesiveness to the resin and are difficult to be directly adhered to each other, are connected to each other via the adhesive sheet. It will be possible to provide glued shoes.

Preferably, the energy absorbing material is a thermoplastic resin, and may be the second thermoplastic resin. In that case, since the second thermoplastic resin that controls the adhesiveness of the second adhesive surface also serves as an energy absorber, it can be easily heated by microwaves while reducing the use of materials that do not contribute to the adhesive function. Adhesive sheets can be used. For example, the energy absorbing material may be a TPU resin.

The first thermoplastic resin may be, for example, an EVA resin. The EVA resin is a resin that is relatively difficult to heat by microwaves, but according to the shoe manufacturing method of the present embodiment, even an adhesive sheet containing EVA resin is heated by microwaves. Therefore, EVA resin can be used as an adhesive element for shoe members. In this case, from the viewpoint of adhesiveness to the first shoe member, EVA resin or polyethylene resin is exposed on the surface of the first shoe member to be adhered to the first surface. Is preferable.

The shoe manufacturing method and shoes according to the present invention are not limited to the configuration of the above embodiment. Further, the manufacturing method and shoes according to the present invention are not limited by the above-mentioned effects. The manufacturing method and shoes according to the present invention can be variously modified without departing from the gist of the present invention.

Further, although no further detailed description will be given here, the present invention relates to technical matters conventionally known for manufacturing methods and shoes, even if the matters are not directly described above. It can also be adopted as appropriate.

1: Shoes 2: First shoe member (midsole), 2A: First bonded surface 3: Second shoe member (upper material), 3B: Second bonded surface 10, 20, 30 , 40: Adhesive sheet, 10A, 20A, 30A, 40A: First surface, 10B, 20B, 30B, 40B: Second surface 11,21: First spare sheet, 12, 22: Second spare sheet , 23: 3rd spare sheet, 41: 1st resin fiber, 42: 2nd resin fiber 111,211,311,411: 1st thermoplastic resin, 121,221,321,421: 2nd Thermoplastic resin

Claims (16)

1. An adhesive sheet containing at least a first thermoplastic resin and an energy absorbing material having a higher dielectric loss rate than the first thermoplastic resin, the first surface of the adhesive sheet and the first surface of the adhesive sheet. A sheet preparation step of preparing an adhesive sheet, wherein the first thermoplastic resin is exposed on at least the first surface of the second surface opposite to the surface of the above.
   The first adhered surface formed on the first shoe member is brought into contact with the first surface, and the second adhered surface formed on the second shoe member is brought into contact with the second surface. With the contact step to bring it into contact with
   After the contact step, the adhesive sheet is heated and melted by irradiating the adhesive sheet with microwaves, and the first shoe member and the second shoe member are used for adhesion. A method of making a shoe, including a gluing step that glues through a sheet.
2. The adhesive sheet contains a second thermoplastic resin of a type different from that of the first thermoplastic resin.
   On the first surface, the abundance ratio of the first thermoplastic resin is larger than the abundance ratio of the second thermoplastic resin, and on the second surface, the abundance ratio of the second thermoplastic resin is The method for producing a shoe according to claim 1, which is larger than the abundance ratio of the first thermoplastic resin.
3. The method for manufacturing shoes according to claim 1 or 2, wherein the energy absorbing material is a thermoplastic resin.
4. The method for manufacturing shoes according to claim 2, wherein the energy absorbing material is the second thermoplastic resin.
5. The method for manufacturing shoes according to claim 3 or 4, wherein the energy absorbing material is a TPU resin.
6. The method for manufacturing shoes according to any one of claims 1 to 5, wherein the adhesive sheet includes two or more laminated spare sheets.
7. The method for manufacturing shoes according to any one of claims 1 to 6, wherein the first thermoplastic resin is EVA resin.
8. The method for manufacturing shoes according to claim 7, wherein EVA resin or polyethylene resin is exposed on the first adhesive surface of the first shoe member.
9. Prior to the contact step, an aqueous primer is applied to at least one of the first surface, the second surface, the first adhered surface, and the second adhered surface. The method for manufacturing a shoe according to any one of claims 1 to 8, further comprising a primer application step.
10. An adhesive sheet containing a first thermoplastic resin and an energy absorbing material having a higher dielectric loss with respect to microwave waves than the first thermoplastic resin, and the first surface of the adhesive sheet. An adhesive sheet having the first thermoplastic resin exposed on at least the first surface of the second surface opposite to the first surface.
    The first shoe member adhered to the first surface and
    A shoe comprising a second shoe member adhered to the second surface.
11. The adhesive sheet contains a second thermoplastic resin of a type different from that of the first thermoplastic resin, and the abundance ratio of the first thermoplastic resin on the first surface is the second. The shoe according to claim 10, wherein the abundance ratio of the second thermoplastic resin is larger than the abundance ratio of the first thermoplastic resin on the second surface. ..
12. The shoe according to claim 10 or 11, wherein the energy absorbing material is a thermoplastic resin.
13. The shoe according to claim 11, wherein the energy absorbing material is the second thermoplastic resin.
14. The shoe according to claim 12 or 13, wherein the energy absorbing material is a TPU resin.
15. The shoe according to any one of claims 10 to 14, wherein the first thermoplastic resin is an EVA resin.
16. The shoe according to claim 15, wherein EVA resin or polyethylene resin is exposed on the surface of the first shoe member to be adhered to the first surface.

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